Apparatus for aerating liquids



Dec. 1, 1936. G. s. HIGGlNsoN APPARATUS FOR AERATING LIQUIDS Filed Jan. 2, 1934 7 Sheets-Sheet l Dec. l, 1936. G. s. HIGGlNsoN APPARATUS FOR AERATING LIQUIDS Filed Jan. 2, 1954 7 Sheets-Sheet 2 Dec l, 1936- G. s. HIGGlNsoN 2,062,995

APPARATUS FOR AERATING LIQUIDSV Filed Jan. 2, 1934 7 Sheets-Sheet 5 \24 I 7 WIIIIIIIAWII/ l m 2o 22 25 f Dec. 1, 1936.

' G. S. HIGGINSON APPARATUS FOR AERATING LIQUIDS 7 Sheets-Sheet 5 Filed Jan. 2, 1934 Dec. 1, 1936- G. s. HIGGxNsoN APPARATUS FOR AERATING LIQUIDS Filed Jan. 2, 1954 7 Sheets-Sheet 6 Dec. 1, 1936. G. s. HIGGlNsoN 2,062,995

APPARATUS FOR AERATING LIQUIDS Filed Jan. 2, 1934 7 sheets-sheet '7 Patented Dec. l, 1936 UNITED STATES PATENT OFFICE APPARATUS FOR AERATING LIQUIDS George Seymour Higginson, London, England,

assigner to Julius C. Vredenburg, London, England 10 Claims.

This invention relates to an apparatus for aerating liquids for beverage purposes.

It relates more particularly to apparatus for aerating liquids; for example, for the manufacture of aerated water and the like and delivering it into bottles or glasses for consumption, of the kind in which the flow of liquid and gas into and out of the apparatus is controlled by a movable plate or disc communicating through ports on its faces, in appropriate succession, with mouths or ports of passages through said members as the plate or disc is moved into different positions.

It is among the objects of the invention to provide a simple, efficient, reliable, safe and inexpensive machine or apparatus of the kind referred to.

The present application is a continuation in part of my copending application, Serial No. 649,039, filed December 27th, 1932, entitled Apparatus for aerating liquids.

In operation the apparatus may be made to conform to the three following conditionSI-(l) where the single or mixed liquid is discharged into a glass or other receptacle under the action 05 of gravity alone, (2) where the glass or receptacle precontains some liquid of a viscous character such as syrup, which is rst diluted and agitated by a portion of the discharge being under pressure in the form of a needle-like spray while the remainder of the quantity is discharged under gravity, (3) where the entire discharge of the single or mixed liquid is made under pressure with or without the rst portion being in the form of a ne needle-like jet.

A highly eiiective and rapid mixing of liquid and gas is achieved through the disposal of the gas inlet and liquid outlet ports as to be closely adjacent and coaxial one with the other.

In those cases where no main supply of liquid is available, an open vessel is added to the apparatus and may be graduated to allow an exact quantity to flow into the aerating chamber, in which case there is no overplus of liquid.

Again where an intimate mixture of two liquids is required, such as water with a syrup, spirit or wine; wine with a diluent or reinforcer; milk with a syrup or liquid eggs etc., the open vessel may be replaced by a closed chamber into which the second component liquid is admitted.

Means are provided for the recovery of any overplus of liquid resulting from the small difference in time between the coincidental operation of emptying the discharge chamber and relling the aerating chamber.

In the accompanying drawings:-

Fig. 1 is a composite Vertical section of one form of the apparatus according to the present invention, the section of the upper member being taken on the line A-A of Fig. 2, the section of the disc valve being taken on the line B-B of 5 Fig. 3 and the section of the lower member being taken on the line C--C of Fig. 4.

Fig. 2 is a plan View oi the apparatus, partly in section,

Fig. 3 is a plan view of the disc valve, drawn to a larger scale,

Fig. 4 is a plan View of the lower member of the apparatus,

Fig. 5 is a vertical section taken on the line K-K 0f Fig. 2,

Fig. 6 is a fragmentary vertical section taken on the line D-D of Fig. 3,

Fig. '7 is a fragmentary vertical section taken on the line E--E of Fig. 3,

Fig. 8 is a vertical section taken on the line F-F of Fig. 3,

Fig. 9 is a fragmentary vertical section taken on the line I-I-I-I of Fig. 3,

Fig. 10 is a fragmentary vertical section taken on the line J-J of Fig. 3,

Figs. 11, 12 and 13 are diagrammatic plan views of the disc valve in various positions,

Fig. 14 is a view similar to Fig. 13 of a modication.

Figs. 15, 16 and 17 are views similar to Figs. 30 l1, 12 and 13 showing a further modified form of disc valve in various positions,

Fig. 18 is a vertical section of the modified disc valve shown diagrammatically in Figs. to 1'7, taken on the line L-L of Fig. 16.

Fig. 19 is a fragmentary vertical section taken on the line M-M of Fig. 16.

Fig. 20 is a fragmentary vertical section taken on the line N-N of Fig. 16, and

Fig. 21 is a vertical section taken on the line O-O of Fig. 16.

As shown, the apparatus comprises a base or lower member l, an upper member 2 and a disc valve 3, all formed by moulding operations from a non-metallic material, preferably aurea-aldehyde condensation product. In the example shown the disc valve is composed of three sections which are cemented together, this facilitating the formation by moulding of the necessary passages and ports extending therethrough but the disc valve may, if desired, be a unitary moulding having some of the passages formed therein by boring operations.

The substantially cylindrical lower member l has vertically extending passages 4, 5 and 6 formed therein and adapted to be connected at their lower ends to waste, compressed-gas supply and Water supply, respectively. The upper ends of these passages are bored out to receive packing elements of known form, such as shown at 1 for the passages 4 and 5, Fig. 1. As can be seen from Figs. 1, 4 and 5, the upper portions of the passages 4, 5 and 6 are formed in an upstanding boss 8, substantially trefoil-shaped in plan, which is surrounded by a sump 9 into the bottom of which opens the upper end of an auxiliary waste or drain passage I adapted to be connected at its lower end to the main Waste, as through a flexible tube (not shown).

Around the upper edge of the vertical wall of the sump 9 there is formed an annular shoulder or seating II concentric with the passage 4, adapted to receive the lower edge of the valve disc 3 and support same so that its lower surface may be rotated in contact with the upper surfaces of the packing elements 1 in the mouths of the passages 4, and 6.

The means for rotating the valve 3 comprise, in the example shown, a bevel pinion I2, formed or -secured on a shaft I3 having a handle I4, engaging with teeth I5 formed on a bevelled flange I6 extending outwardly from the upper edge of the valve 3. A suitable stop I1 formed on the shaft I3 co-acts with another stop (not shown) disposed in a groove I8 formed in the bearing I9 for the shaft to limit the rotation of the latter to approximately 120. Y

`As seen more clearly from Figs. 4 and 5, the lower member I is formed with a radially extending portion 20 having at its outer end a downwardly directed discharge nozzle 2|. The portion 20 is moulded with an open-topped groove 22 sloping downwardly to the nozzle 2I from beneath a substantially cylindrical chamber 23 formed in a fillet 24 which is moulded separately and inserted in a corresponding recess in the portion 20 to cover the groove 22 therein. A central aperture 25 in the base of the chamber 23 gives access to the lgroove 22 from the latter and a further aperture 26 in the outer end of the fillet 24 is disposed vertically above and co-axially with the nozzle 2I. The chamber 23 is provided with a packing element 1 similar to those already mentioned. VConcentrically with the passage 4 and seating `II, there is`formed on the upper surface of the lower memberV I 'an interrupted annular rib 21 v(Fig. 5) serving to position the upper member 2 ywith respect to the said lower member, these members being suitably secured together by means of bolts or the like (not shown).

The upper face of the disc valve 3 is plane and contacts with the lower faces of the packing elements 1 disposed in various ports or apertures formed in the upper member 2.

Of these ports or apertures, two are comparatively large and two comparatively small, one of each being disposed in the base of a circular recess 28 or 29 formed in the upper surface of the member 2, the vertical cylindrical walls of these recesses being screw-threaded to receive the externally threaded open lower ends of vessels 30 and 3|, respectively.

The larger port or aperture, marked 32, corresponding to the vessel 30 is provided With a packing element 1 having a free passage therethrough marked 32a. (Fig. 1) and the smaller port or aperture, marked 33, corresponding to the vessel 30 is similarly provided with a packing (not shown) having a free aperture hereinafter referred to by the reference 33a (Figs. 11 to 14). The correi sponding ports and free passages for the vessel 3| are designated, respectively, 34, 34a, 35 and 35a.

In the upper portions of the smaller ports 33, 35, which portions are of reduced diameter in the example shown, are secured the lower ends of vertical tubes 36 and 31, respectively, which terminate at their upper ends just short of the inner surfaces of the tops of the vessels 30 and 3 I The upper member 2, which is substantially cylindrical in shape is also formed with a radial extension 3B adapted to be disposed over and substantially coincide with the outer portion of the fillet 24 secured in the portion 20 of the lower member I. At its outer end this extension 38 is formed with a narrow vertical bore 39, co-axial with the nozzle 2l and having secured in its enlarged lower end a nozzle 40 projecting downwardly to extend partially into the aperture 26 formed in the fillet 24.

From the bore 39 there extends radially ofthe member 2 a narrow groove 4I closed on its upper side byan inserted fillet 42 to constitute a narrow passage leading to a vertical bore 43 extending downwardly from the passage centrally of the member 2 to open into a chamber 44 (Fig. 5) provided with a packing 1 having a free aperture 44a in that surface bearing on the upper face of the disc valve 3.

A further port or aperture 45 is formed in the upper member 2 to receive a packing 1 having a free aperture 45a in its lower end and is shown closed by a screw plug 46 at its upper end in Figs. 2 and 5. This plug 4B is removed in certain circumstances, to be hereinafter referred to, so that the lower end of a further receptacle (not shown) may be arranged in the port 45 in its place.

Referring now to the disc valve 3 and Figs. 3, l1, l2 and 13.

The valve 3 is formed with a central opening 41 in its underside which is constantly inregister with the free passage 4a through the packing 1 arranged in the mouth of the waste passage 4. This opening 41 gives access to an annular passage 41a. formed part-way through the Valve 3 and communicating through horizontal passages 48, extending radially of the valve, with the lower ends of vertical bores 49 and 50 which open at their upper ends on the upper face of the valve 3 (Fig. 8). The bores 49 and 50 are arranged so that they may be brought beneath the openings 33a and 35a, respectively, already referred to.

At the same radius as the bore 50 and adjacent thereto there is formed a similar bore 5I communicating through a horizontal passage 48a with the annular passage 41a and a further similar bore 52 communicating with the passage 41a through a horizontal passage 48h.

In a position relative to the bore 49 corresponding to that of the bore 5I with respect to the bore 50 there is formed a bore 53 communicating through a short horizontal passage 4Iic with a further horizontal passage to be hereinafter referred to.

In the underside of the valve 3 is formed a bore 54 (Figs. 3 and 6) at a radius such that it may be brought over the opening of the Water supply passage 6 and in the upper side of the valve there is formed a bore 55 at such a radius and in such a position that it may be brought beneath the opening 32a already referred to at the moment when the bore 54 registers with the passage 6, the bores 54 and 55 communicating with leach other internally of the valve disc through a short horizontal passage 56.

4At approximately the same radius as the port r55 there is formed a pair of concentric ports 51, 60, in the upper side of the disc 3, the inner circular port 51 communicating through a horizontal passage 58 with a vertical port 59 formed in the underside of the disc 3 at a position such that it may be brought into register with the compressed-gas supply passage 5 (Figs. 1, 3 and 7). The outer annular port 60, on the other hand, communicates through a horizontal passage 6I with a vertical port 62 opening into the upper surface of the disc `3 at a position such that it may be brought into register with the opening 34a (Fig. 1) at the moment when the port 60 registers with the opening 32a.

In the underside of the valve 3 is also formed a port 63 (Figs. 3 and 10) adapted to be brought vertically above the opening 25 (Fig. 5) and connected by an upwardly inclined passage 64 with a port 65 formed in the upper Surface of the Valve at a position such that it registers with the opening 34a when the port 63 is disposed above the opening 25.

Centrally of the upper surface of the disc 3 is formed a vertical port 66 registering with the opening 44a already referred to and communicating through a horizontal passage 61 (Figs. 3 and 9) with a port 68 also formed in the upper surface of the disc 3 and adapted to be brought into register with the opening 34a (Figs. 1 and 1l).

Suitably disposed so that it registers with the opening 33a at the moment when the port 68 registers with the opening 34a is a port 69 (Figs. l, 3 and 11) communicating through the passage 18, already referred to, with the passage 48 leading from the port 49 to the annular passage 41a formed centrally of the disc 3.

Although the specic positions of the ports and passages in the valve disc 3 have not been detailed in the above description thereof, it is thought that the following description of the manner in which the apparatus operates to supply aerated mineral water will suflice to indicate the relative positions of the said ports-and passages.

The position of the valve disc 3 when the apparatus is standing at rest with the control handle I4 at one of its limit positions is indicated in Fig. 11. It will be seen that the concentric ports 51, 60 are disposed beneath the opening 32a, the port 59 is disposed over the compressed-gas supply passage 5 and the port 62 is disposed beneath the opening 34a. In this position the vessel 3| contains a charge of aerated water ready to be drawn-off and the vessel 39 contains only gas under pressure.

On the first portion of the movement of the operating handle, which is such that the Valve disc 3 moves clockwise, the supply of gas to the vessel 30 through the port 59, passage 58 and port 51 is cut off and the port 68 is brought beneath the opening 34a, the port 62 having simultaneously moved from beneath said opening. The position of the valve 'disc 3 is then 'that indicated in Fig. 12. In this position some of the aerated water in the vessel 3| is discharged under pressure through the port 68, passage 61, port 66, opening 44a, bore 43, passage 4|, bore 39 and nozzle 4U in the form of a needle-like jet directed through the outlet nozzle 2| into a glass or the like held beneath same and containing a given quantity of syrup. The discharged aerated water therefore becomes intimately admixed with the syrup in the glass` or the like. At the Vsame time the port 69 has been brought beneath the opening 33a and some of the gas under pressure in the vessel 30 is snifted oli through the port 69, passages 10, 48 and 41a to the waste pipe 4. It Will be understood that the valve disc 3 is being moved while such discharging operations are occurring so that they are of short duration.

The continued movement of the handle I4 causes the needle like jet to be cut off, traverses the ports 5| and 50 beneath the opening 35a, and the port 53 beneath the opening 33a, whereby the gas under pressure in the vessel 3| is momentarily snifted off in two stages through pipe 31, ports 5| and 50, passages 48a, 48 and passage 41a to the waste passage 4, and the gas under pressure in the vessel 36 is also momentarilyr snifted off through pipe 36, port 53, passages 48e, 10 and 48 and passage 41a to the passage 4, and then brings ports 49 and 52 beneath the opening 33a and 35a, respectively, the ports 55 and 65 beneath the openings 32a and 34a., respectively, and the ports 54 and 63 above the water supply passage 6 and the opening 25, respectively. The valve 3 is then in the position shown in Fig. 13, the handle I4 being at its other limit position.

It will be seen that the two vessels 3l] and 3| are now open to the atmosphere through the pipes 36 and 31, ports 49 and 52, passages 48, 48h, passage 41a and waste pipe 4, any gas under pressure which may still have been contained in the vessels therefore being discharged down to atmospheric pressure. n

At the same time the charge of aerated water in the vessel 3| is discharged under the action of gravity through the opening 34a, port 65, passage 64, port 63, opening 25, passage 22 and nozzle 2| into the glass or the like held therebeneath, while water from the supply pipe or passage 6 flows through the port 54, passage 56, port 55 and` opening 32a into the Vessel 30.

On the handle I4 being moved back to its initial limit position the communications from the vessels 36 and 3| to the atmosphere, and to the water supply and discharge nozzle, respectively, are interrupted and the disc valve 3 is moved back (anti-clockwise) until it again reaches the position shown in Fig. 1l.

Gas under pressure is immediately admitted from the pipe or passage 5 to the vessel 39, by way of the port 59, passage 58, port 51 and opening 32a (see Fig. 1) and this enters the water already contained in the vessel while simultaneously forcing it out therefrom, through the annular port 68, passage 6I, port 62 and opening 34a, into the vessel 3|. Due to the concentric arrangement of the ports 51 and 60 a very eifective and thorough intermixing of the gas under pressure with the water is brought about, the incoming stream of gas meeting the outgoing stream of water adjacent the opening 32a land aerating same instantaneously.

Upon the completion of the transfer of the water from the vessel 30 to the vessel 3| the cycle of operations is completed, the vessel 3| being again filled with a charge of aerated water ready to be drawn off.

Any leakages of liquid which may occur within the housings I and 2 collect in the sump 9 from Vwhich they drain away through the auxiliary than water, for example milk or wine, in circum` the syrup is stored. Vlatter pressure provides an easy and exact method stances where a definite ymeasure is required, or where there is no means for carrying off overplus or waste. In this case the plug 46 (Fig. 5) is removed from the mouth of the port 45 and an open mouthed vessel (not shown) is screwed in the said mouth. rI'his vessel which is preferably graduated to act as a measure, is lled with the requisite quantity of liquid, and the normal Water supply to the apparatus is interrupted, preferably by plugging the port 54.

The disc valve 3 has a further port 1| formed in its face at such a position that it registers with the opening 45a. when the shifting ports 49 and 52 are operative (see Fig. 14), this port 1| communicating through an angular passage 12 in the Valve body with the port 55 therein.

With the valve 3 in the position indicated in Fig. 14, the vessels 30 and 3| are open to the atmosphere in the manner already described with reference to Fig. 13 and the supply of milk or the like from the open-topped vessel (not shown) ilows by gravity, through the opening 45a, port 1|, passage 12, lport 55 and opening 32a into the vessel 30.

Further movements of the disc valve 3, in the manner already described, interrupt the communication between the open-topped vessel and the vessel 30, admit gas under pressure to the latter to aerate the liquid and force it into the vessel 3|, snift the vessels 30 and 3| to atmosphere and allow the aerated liquid to discharge from the vessel 3| under the action of gravity, through the nozzle 2|, into a glass or the like.

Referring now'to Figs. 15 to 21, there is shown here a modied disc valve 3 intended for the case where the open-mouthed vessel referred to in connection with Fig. 14 is removed from the screwed mouth of the port 45 (Fig. 5) and replaced by a closed vessel or chamber (not shown) resembling the chambers 3D and 3| (Fig. 1). In these iigures parts already described or parts corresponding thereto are indicated by the same reference numerals.

The disc Valve is formed with a further port in its upper surface which is adapted to register with the opening 45a. when the port 55 is disposed beneath the opening 32m (see Fig. 15), this port |09 being in communication, through a paslsage formed through the disc valve, with a port |02 formed in the under surface of the latter and adapted to register at this moment also with a syrup inlet (not shown) corresponding in essentials with the water inlet 6 (Fig. 4). n l

This syrup inlet is constantly connected to a store of syrup kept under pressure so that, in the position of the disc valve shown in Fig. l5, syrup cws through the port |02, passage IDI, port |85) and opening 45a into the closed chamber (not shown) screwed into the mouth of the port 45, and fills said chamber to an extent determined by the pressure under which the syrup is stored due to the fact that the gas or air trapped in the chamber is compressed into the upper part thereof until its pressure equals that under which Hence regulation of the of measuring the quantity of syrup supplied to the chamber at each operation of the disc valve 3.

In addition, the port 62 adapted to register with theopening 34a at the time that the port 59 registers with the gas inlet 5 (see Fig. 16) is no longer connected directly to the annular port 66 adapted to come beneath the opening 32a at this` moment by the passage 6|, but is, instead, connected by .the passage 6| to an annular port 60a of a pair of concentric ports adapted at the said instant to come beneath the aperture 45a, the inner circular port 51a of which pair is connected in turn to the said annular port 60 by a passage 6| a.

The disposition of the ports 59, 51, 6|), 51a., 60a

and 62 is such, as will be seen from a consideration of Figs. 16 and 17, that the ports 51, 60, 51a, 60a and 62 remain in communication with the respective openings 32a, 45a and 34a during an angular movement of the disc valve 3 correspondi water is flowing into chamber 30, from inlet 6, 1

through port 54, passage 56, port 55 and opening 32a, syrup is flowing into the third closed chamber (not shown) through port |02, passage port |50 and opening 45a, and the chamber 3| is open to the atmosphere both through the dis-I charge conduit 22, opening 25, port 63, passage 54, port 65 and opening 34a and through the vent tube 31, opening 35a, port 52, passage 48h and opening 4e.

During the movement of the handle to the other limiting position, the valve disc 3 is moved through successive positions for ensuring the followingsequence of operationsr-the displacement of the ports 55, |00, 65, 49 and 52 from beneath the openings 32a, 45a, 34a, 33a and 35a., respectively,

so that the three chambers are isolated from the atmosphere and from the liquid and syrup supplies; the simultaneous bringing of the ports 51, 60 beneath the opening 32a, ofthe ports 51a, 60a, beneath the opening 45a, of the port 62 beneath the opening 34a. and of the port 59 above the gas inlet 5, so'that gas under pressure iiows through port 51 into the water in the chamber 30, aerates same and drives it out through port 60, passage VS |ci and port 51a into the syrup in the third chamber (not shown), where it mixes with and also aerates the said syrup and drives the mixture out through port 66a, passage 6| and port 62 into the discharge chamber 3| (see Fig. 16) the displacement of the port 59 from above the gas inlet 5 and the bringing of the snift ports 5|, 50 beneath the opening 35a, with the ports 51 and 60, 51a and 60a and 62 still beneath the openings 32a,

.45a and 34a, respectively, so that excess gas pressure may be snifted off from the three chambers in the following manner, i. e. from the chamber through the port 66, passage 6|a, port 51 and opening 45a into the third chamber (not shown),l

from the latter chamber through port 60a, passage 6|, port 62 and opening 34a into the chamand, .after having bubbled through the. aerated charge in the latter, through the vent tube 31, opening a, ports 50, 5|, passages 48, 48a and opening 4a to the waste pipe 4; and, nally, the bringing of the port 65 beneath the opening 34a, the port 52 beneath the opening 35a., the port |00 beneath the opening 45a, the port 55 beneath the opening 32a and the port 69 beneath the opening 33a, so that the aerated charge in the cham ber 3| is discharged, under the action of gravity, through the opening 34a, port 65, passage 64, port 63, opening 25 and passage 22 to the nozzle 2|, the chamber 30' is again filled with water and the third chamber (not shown) is again iilled with syrup.

The apparatus is now again in readiness for aerating and delivering a fresh charge of a mixture of syrup and water. It will be understood that the syrup referred to in the above description may be replaced by any other desired liquid, such as a liquid containing colouring matter or the like, if desired.

What I claim is:

1. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a vessel for liquid, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, and means operable by the movement of said valve to first cause, discharge of liquid under pressure from the bottom of said vessel and then by gravity,

2. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a vessel for liquid, a discharge member having a passage therein for the ovv of aerated liquid out of the apparatus, and means operable by the movement of said valve to first cause discharge of liquid under pressure axially of said discharge passage and then by gravity.

3. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid to ow into one vessel and then therefrom into a second vessel, a discharge member having a passage therein for the ow of aerated liquid out of the apparatus, and means operable by the mo-vement of said valve to rst cause discharge of liquid under pressure from the bottom of said second vessel and then by gravity.

4. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid to flow into one vessel and then therefrom into a second vessel, the liquid leaving the first vessel by an outlet concentric with the gas inlet, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, and means operable by the movement of 'said valve tofirst cause discharge of liquid under pressure from the bottom of said second vessel and then by gravity.

5. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allo-w gas and liquid to flow thereinto and then therefrom into a further vessel, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, and means operable by the movement of said valve to first cause discharge of liquid under pressure from the bottom of said second vessel and then by gravity, said pluralityv of vessels containing different liquids.

6. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid under pressure to flow into one vessel and then therefrom into a second vessel, a discharge member having a passage therein for the iiow of aerated liquid out of the apparatus, and means operable by the movement of said valve to rst cause discharge of liquid under pressure from the bottom of said second vessel and then by gravity.

'7. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allo-w gas and liquid to fiow thereinto and then therefrom into a further vessel, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, means operable by the movement of said valve to first cause discharge of liquid under pressure and then by gravity and means for forcing diiferent liquids under pressure into said plurality of vessels.

8. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid to flow thereinto and then therefrom into a further vessel, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, means operable by the movement of said valve to rst cause discharge of liquid under pressure and then by gravity, means for forcing different liquids under pressure into said plurality of vessels and means for varying said pressure in order to control the quantity of said liquid supplied to said plurality of vessels.

9. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid to now into one vessel and then therefrom into a second vessel, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, means operable by the movement of said valve to first cause discharge of liquid under pressure from the bottom of said second vessel and then by gravity and means for forcing liquid under pressure into said rst vessel.

l0. An apparatus for aerating liquids comprising a lower member, an upper member, a disk valve therebetween, cooperating passages in said valve and members, means for allowing the entrance of gas and of liquid into said apparatus, a plurality of vessels so connected as to allow gas and liquid to flow into one vessel and then therefrom into a second vessel, a discharge member having a passage therein for the flow of aerated liquid out of the apparatus, means operable by the movement of said valve to rst cause discharge of liquid under pressure and then by gravity, means for forcing liquid under pressure into said first vessel and means for varying said pressure in order to control the quantity of said liquid supplied to said rst vessel.

GEORGE SEYMOUR HIGGINSON. 

